BACKGROUND: Although emphysema destroys alveolar structures progressively and causes death eventually, no drug has been discovered to prevent, intervene, and/or resolve this life-threatening disease. We recently reported that sulfated caffeic acid dehydropolymer CDSO3 is a novel potent triple-action inhibitor of elastolysis, oxidation, and inflammation in vitro, and therefore, a potential anti-emphysema agent. However, the in vivo therapeutic potency, duration and mode of actions, and effective route remain to be demonstrated. METHODS: Emphysema was induced in rats with human sputum elastase (HSE) combined with cigarette smoke extract (CSE). CDSO3 at 5, 30, or 100 μg/kg was dosed to the lung or injected subcutaneously at 2, 6, or 24 h before or 1 or 24 h or 1 week after the HSE/CSE instillation. At 1 h or 48 h or on day 21-22 or day 28, lungs were examined for airway-to-blood injurious barrier damage; their elastolytic, oxidative, and inflammatory activities; lung luminal leukocytes infiltration; functional treadmill exercise endurance; and/or morphological airspace enlargement. RESULTS: CDSO3, when dosed to the lung at 30 or 100 μg/kg, but not via systemic subcutaneous injection, significantly (43-93 %) attenuated HSE/CSE-induced (1) barrier damage measured by luminal hemorrhage and protein leak; (2) elastolytic, oxidative, and inflammatory activities measured with elastase, reduced glutathione, and TNFα levels, respectively; (3) luminal neutrophil infiltration and tissue myeloperoxidase activity; (4) functional impairment of exercise endurance; and (5) airspace enlargement, in both preventive and interventional dosing protocols. Notably, the effects were shown to last for 24 h at the greater 100-μg/kg dose, and the 1-week-delayed administration was also capable of attenuating the development of emphysema. CONCLUSIONS: CDSO3 is a novel, potent, long-acting, nonpeptidic macromolecule that inhibits HSE/CSE-induced elastolysis, oxidation, and inflammation in the lung and thereby attenuates the development of emphysema in rats, in both preventive and interventional manners, when administered locally to the lung.
BACKGROUND: Although emphysema destroys alveolar structures progressively and causes death eventually, no drug has been discovered to prevent, intervene, and/or resolve this life-threatening disease. We recently reported that sulfated caffeic acid dehydropolymerCDSO3 is a novel potent triple-action inhibitor of elastolysis, oxidation, and inflammation in vitro, and therefore, a potential anti-emphysema agent. However, the in vivo therapeutic potency, duration and mode of actions, and effective route remain to be demonstrated. METHODS:Emphysema was induced in rats with human sputum elastase (HSE) combined with cigarette smoke extract (CSE). CDSO3 at 5, 30, or 100 μg/kg was dosed to the lung or injected subcutaneously at 2, 6, or 24 h before or 1 or 24 h or 1 week after the HSE/CSE instillation. At 1 h or 48 h or on day 21-22 or day 28, lungs were examined for airway-to-blood injurious barrier damage; their elastolytic, oxidative, and inflammatory activities; lung luminal leukocytes infiltration; functional treadmill exercise endurance; and/or morphological airspace enlargement. RESULTS:CDSO3, when dosed to the lung at 30 or 100 μg/kg, but not via systemic subcutaneous injection, significantly (43-93 %) attenuated HSE/CSE-induced (1) barrier damage measured by luminal hemorrhage and protein leak; (2) elastolytic, oxidative, and inflammatory activities measured with elastase, reduced glutathione, and TNFα levels, respectively; (3) luminal neutrophil infiltration and tissue myeloperoxidase activity; (4) functional impairment of exercise endurance; and (5) airspace enlargement, in both preventive and interventional dosing protocols. Notably, the effects were shown to last for 24 h at the greater 100-μg/kg dose, and the 1-week-delayed administration was also capable of attenuating the development of emphysema. CONCLUSIONS:CDSO3 is a novel, potent, long-acting, nonpeptidic macromolecule that inhibits HSE/CSE-induced elastolysis, oxidation, and inflammation in the lung and thereby attenuates the development of emphysema in rats, in both preventive and interventional manners, when administered locally to the lung.
Authors: Y Shinguh; A Yamazaki; N Inamura; K Fujie; M Okamoto; K Nakahara; Y Notsu; M Okuhara; T Ono Journal: Eur J Pharmacol Date: 1998-03-26 Impact factor: 4.432
Authors: D Lapenna; A Mezzetti; S de Gioia; G Ciofani; L Marzio; C Di Ilio; F Cuccurullo Journal: Biochem Pharmacol Date: 1992-07-07 Impact factor: 5.858
Authors: Robert A Pouliot; Patrick A Link; Nabil S Mikhaiel; Matthew B Schneck; Michael S Valentine; Franck J Kamga Gninzeko; Joseph A Herbert; Masahiro Sakagami; Rebecca L Heise Journal: J Biomed Mater Res A Date: 2016-04-06 Impact factor: 4.396
Authors: Gao Zhen; Wang Jing; Jing Jing; Dan Xu; Li Zheng; Fengsen Li Journal: Evid Based Complement Alternat Med Date: 2018-07-18 Impact factor: 2.629